Thermodynamic integration with harmonic reference: Difference between revisions

Revision as of 08:10, 1 November 2023

The Helmholtz free energy ( $A$ ) of a fully interacting system (1) can be expressed in terms of that of system harmonic in Cartesian coordinates (0, $\mathbf{x}$ ) as follows

{\displaystyle A_{1} = A_{0,\mathbf{x}} + \Delta A_{0,\mathbf{x}\rightarrow 1} }

where $\Delta A_{0,\mathbf{x}\rightarrow 1}$ is anharmonic free energy. The latter term can be determined by means of thermodynamic integration (TI)

{\displaystyle \Delta A_{0,\mathbf{x}\rightarrow 1} = \int_0^1 d\lambda \langle V_1 -V_{0,\mathbf{x}} \rangle_\lambda }

with $V_i$ being the potential energy of system $i$ , $\lambda$ is a coupling constant and $\langle\cdots\rangle_\lambda$ is the NVT ensemble average of the system driven by the Hamiltonian

{\displaystyle \mathcal{H}_\lambda = \lambda \mathcal{H}_1 + (1-\lambda)\mathcal{H}_{0,\mathbf{x}} }

Free energy of harmonic reference system within the quasi-classical theory writes

{\displaystyle A_{0,\mathbf{x}} = A_\mathrm{el}(\mathbf{x}_0) - k_\mathrm{B} T \sum_{i = 1}^{N_\mathrm{vib}} \ln \frac{k_\mathrm{B} T}{\hbar \omega_i} }

with the electronic free energy $A_\mathrm{el}(\mathbf{x}_0)$ for the configuration corresponding to the potential energy minimum with the atomic position vector $\mathbf{x}_0$ , the number of vibrational degrees of freedom $N_\mathrm{vib}$ , and the angular frequency $\omega_i$ of vibrational mode $i$ obtained using the Hesse matrix $\underline{\mathbf{H}}^\mathbf{x}$ . Finally, the harmonic potential energy is expressed as

{\displaystyle V_{0,\mathbf{x}}(\mathbf{x}) = V_{0,\mathbf{x}}(\mathbf{x}_0) + \frac{1}{2} (\mathbf{x} - \mathbf{x}_0)^T \underline{\mathbf{H}}^\mathbf{x} (\mathbf{x} - \mathbf{x}_0) }

Thus, a conventional TI calculation consists of the following steps:

determine $\mathbf{x}_0$ and $V_{0,\mathbf{x}}(\mathbf{x}_0)$ in structural relaxation
compute $\omega_i$ in vibrational analysis
use the data obtained in the point 2 to determine $\underline{\mathbf{H}}^\mathbf{x}$ that defines the harmonic forcefield
perform NVT MD simulations for several values of $\lambda \in \langle0,1\rangle$ and determined $\langle V_1 -V_{0,\mathbf{x}} \rangle$

@@ Line 29: / Line 29: @@
 # compute <math>\omega_i</math> in vibrational analysis
 # use the data obtained in the point 2 to determine <math>\underline{\mathbf{H}}^\mathbf{x}</math> that defines the harmonic forcefield
-# perform NVT MD simulations for several values of  <math>\lambda \in <0,1></math> and determined <math>\langle V_1 -V_{0,\mathbf{x}}  \rangle</math>
+# perform NVT MD simulations for several values of  <math>\lambda \in \langle0,1\rangle</math> and determined <math>\langle V_1 -V_{0,\mathbf{x}}  \rangle</math>
 #